Track and hold circuits for high speed and interleaved adcs

ABSTRACT

Improved track and hold (T/H) circuits can help analog-to-digital converters (ADCs) achieve higher performance and lower power consumption. The improved T/H circuits can drive high speed and interleaved ADCs, and the design of the circuits enable additive and multiplicative pseudo-random dither signals to be injected in the T/H circuits. The dither signals can be used to calibrate (e.g., linearize) the T/H circuits and the ADC(s). In addition, the dither signal can be used to dither any remaining non-linearity, and to calibrate offset/gain mismatches in interleaved ADCs. The T/H circuit design also can integrate an amplifier in the T/H circuit, which can be used to improve the signal-to-noise ratio (SNR) of the ADC or to act as a variable gain amplifier (VGA) in front of the ADC.

PRIORITY APPLICATION

This patent application claims priority to and receives benefit from U.S. Provisional Application, Ser. No. 62/578,110, titled “TRACK AND HOLD CIRCUITS FOR HIGH SPEED AND INTERLEAVED ADCS”, filed on Oct. 27, 2017. This patent application further claims priority to, and is a continuation-in-part of, U.S. patent application Ser. No. 16/119,186, titled “TRACK AND HOLD CIRCUITS FOR HIGH SPEED AND INTERLEAVED ADCS”, filed on Aug. 31, 2018. The above-noted applications are hereby incorporated in their entirety.

TECHNICAL FIELD OF THE DISCLOSURE

The present disclosure relates to the field of integrated circuits, in particular to track and hold circuits for analog-to-digital converters (ADCs).

BACKGROUND

In many electronics applications, an ADC converts an analog input signal to a digital output signal, e.g., for further digital signal processing or storage by digital electronics. Broadly speaking, ADCs can translate analog electrical signals representing real-world phenomenon, e.g., light, sound, temperature, electromagnetic waves, or pressure for data processing purposes. For instance, in measurement systems, a sensor makes measurements and generates an analog signal. The analog signal would then be provided to an ADC as input to generate a digital output signal for further processing. In another instance, a transmitter generates an analog signal using electromagnetic waves to carry information in the air or a transmitter transmits an analog signal to carry information over a cable. The analog signal is then provided as input to an ADC at a receiver to generate a digital output signal, e.g., for further processing by digital electronics.

Due to their wide applicability in many applications, ADCs can be found in places such as broadband communication systems, audio systems, transmitter systems, receiver systems, etc. Designing circuitry in ADC is a non-trivial task because each application may have different needs in performance, power, cost, and size. ADCs are used in a broad range of applications including Communications, Energy, Healthcare, Instrumentation and Measurement, Motor and Power Control, Industrial Automation and Aerospace/Defense. As the applications needing ADCs grow, the need for fast yet accurate conversion also grows.

BRIEF DESCRIPTION OF THE DRAWINGS

To provide a more complete understanding of the present disclosure, features and advantages thereof, reference is made to the following description, taken in conjunction with the accompanying figures, wherein like reference numerals represent like parts, in which:

FIG. 1 shows a track and hold circuit driving M ADCs of a time-interleaved ADC, according to some embodiments of the disclosure;

FIG. 2 shows an exemplary track and hold circuit having two buffers and a switched-capacitor network in between, according to some embodiments of the disclosure;

FIG. 3 shows an exemplary track and hold circuit having a buffer, a switched-capacitor network, and an amplifier, according to some embodiments of the disclosure;

FIG. 4 shows an exemplary track and hold circuit illustrating one exemplary switched-capacitor network with sampling and dither injection, according to some embodiments of the disclosure;

FIG. 5 shows an exemplary track and hold circuit illustrating another exemplary switched-capacitor network with sampling and dither injection, according to some embodiments of the disclosure;

FIG. 6 shows an exemplary track and hold circuit illustrating yet another exemplary switched-capacitor network with sampling and dither injection, according to some embodiments of the disclosure;

FIG. 7 shows an exemplary track and hold circuit with multiple hold buffers, according to some embodiments of the disclosure;

FIG. 8A shows an exemplary track and hold circuit with multiple sampling networks, according to some embodiments of the disclosure;

FIG. 8B illustrates timing for the track and hold circuit of FIG. 8A, according to some embodiments of the disclosure;

FIG. 9 shows another exemplary track and hold circuit with multiple sampling networks, according to some embodiments of the disclosure;

FIG. 10 shows yet another exemplary track and hold circuit with multiple sampling networks, according to some embodiments of the disclosure;

FIG. 11 shows an exemplary track and hold circuit with multiple time-interleaved sampling networks and a single hold buffer, according to some embodiments of the disclosure;

FIG. 12 shows an exemplary track and hold circuit with multiple time-interleaved sampling networks and multiple hold buffers, according to some embodiments of the disclosure;

FIG. 13A shows an exemplary track and hold circuit with chopping to inject a multiplicative dither, according to some embodiments of the disclosure;

FIG. 13B illustrates integrating the chopper with a switch in the sampling network, according to some embodiments of the disclosure;

FIG. 14 shows another exemplary track and hold circuit with chopping to inject a multiplicative dither, according to some embodiments of the disclosure;

FIG. 15 shows an exemplary track and hold circuit with multiple sampling networks with chopping added to inject a multiplicative dither, according to some embodiments of the disclosure;

FIG. 16 shows another exemplary track and hold circuit with chopping to inject a multiplicative dither, according to some embodiments of the disclosure;

FIG. 17A show an exemplary track and hold circuit driving 8 slices, according to some embodiments of the disclosure;

FIG. 17B show a timing diagram for controlling two serial switches in the circuit illustrated by FIG. 17A, according to some embodiments of the disclosure;

FIG. 18 shows a flow diagram illustrating a method for sampling an input signal with calibration, according to some embodiments of the disclosure;

FIG. 19 shows an example signal flow diagram of a track and hold circuit with a balun, according to some embodiments of the disclosure.

FIG. 20 shows an example configuration of a balun and a related behavioral model, according to some embodiments of the disclosure.

FIG. 21 shows an example configuration of a balun with a matching circuit, according to some embodiments of the disclosure.

FIG. 22 shows an alternative example configuration of a track and hold circuit with a balun, according to some embodiments of the disclosure.

FIG. 23 shows an alternative example configuration of a track and hold circuit with a balun, according to some embodiments of the disclosure.

DETAILED DESCRIPTION

Overview

Improved track and hold (T/H) circuits can help ADCs achieve higher performance and lower power consumption. The improved T/H circuits can drive high speed and interleaved ADCs, and the design of the circuits enable additive and multiplicative pseudo-random dither signals to be injected in the T/H circuits. The dither signals can be used to calibrate (e.g., linearize) the T/H circuits and the ADC(s). In addition, the dither signal can be used to dither any remaining non-linearity, and to calibrate offset/gain mismatches in interleaved ADCs. The T/H circuit design also can integrate an amplifier in the T/H circuit, which can be used to improve the signal-to-noise ratio (SNR) of the ADC or to act as a variable gain amplifier (VGA) in front of the ADC.

High Speed ADCs

ADCs are electronic devices that convert a continuous physical quantity carried by an analog signal to a digital output or number that represents the quantity's amplitude (or to a digital signal carrying that digital number). An ADC can be defined by the following application requirements: its speed (number of samples per second), its power consumption, its bandwidth (the range of frequencies of analog signals it can properly convert to a digital signal) and its resolution (the number of discrete levels the maximum analog signal can be divided into and represented in the digital signal). An ADC also has various specifications for quantifying ADC dynamic performance, including signal-to-noise-and-distortion ratio (SINAD), effective number of bits (ENOB), SNR, total harmonic distortion (THD), total harmonic distortion plus noise (THD+N), and spurious free dynamic range (SFDR). ADCs have many different designs, which can be chosen based on the application requirements and specifications.

To achieve higher speeds, interleaving is used to increase the sample rate of ADCs. A time-interleaved ADC can use M ADCs to sample an analog input signal to produce digital outputs. The M ADCs (referred herein as the M slices or M channels), operating in a time-interleaved fashion, can increase the sampling speed several times compared to the sampling speed of just one ADC. The M ADCs can be used in parallel, where the M ADCs can operate to sample an analog input one after another in a time-interleaved fashion. Using appropriate clocking to control the ADCs can greatly increase the effective combined ADC sampling rate. In some cases, the M ADCs are selected sequentially one after another to sample the input signal. In some other cases, the M ADCs can be selected in a pseudo-randomized fashion. Since not all M ADCs are exactly matched or the same, discrete tones (or spurs) would be present if the selection was sequential, e.g., where the M ADCs are used according to a fixed sequence. Pseudo-randomization can help spread the discrete mismatch error tones into the noise floor of the spectrum of the ADC output.

High speed ADCs, typically running at speeds on the order of giga-samples per second, are particularly important in fields such as communications and instrumentation. The input signal can have a frequency in the giga-hertz range, and the ADC may need to sample in the range of giga-samples per second. High frequency input signals can impose many requirements on the circuits receiving the input signal, i.e., the “front end” circuitry of the ADC. The circuit not only has to be fast, for some applications, the circuit needs to meet certain performance requirements, such as SNR and SFDR. Designing an ADC that meets speed, performance, area, and power requirements is not trivial, since faster speeds and higher performance often come at the cost of area and power.

High Speed Track and Hold (T/H) Circuits

Track and hold (T/H) circuits can be an important part of the input circuitry for ADCs. T/H circuits convert the continuous-time input signal into a discrete-time held signal for the ADC(s) which follow the T/H circuits. The ADC(s) can perform conversion based on the discrete-time held signal provided by the T/H circuit. For interleaved ADCs with M ADCs, separate T/H circuits can be provided for each one of the M ADCs, where the individual T/H circuits can run at the (slower) speed of the M ADCs. Running them at the speed of the M ADCs can make the T/H circuits simpler to design. However, distributing the T/H circuits to the M channels means there can be timing and/or bandwidth mismatch between the M channels, since the T/H circuits may not be exactly the same for the M channels. Timing and bandwidth mismatches can be very difficult to measure and address, especially at high speeds.

A different approach is to use a single or dedicated T/H circuit for multiple time-interleaved ADCs so as to avoid timing and/or bandwidth mismatches between the channels. FIG. 1 shows a track and hold circuit driving M ADCs of a time-interleaved ADC, according to some embodiments of the disclosure. FIG. 1 shows a T/H circuit 104 driving M ADCs operating in a time-interleaved fashion, shown as Slice 102 ₁, Slice 102 ₂, . . . Slice 102 _(M) of a time-interleaved ADC, according to some embodiments of the disclosure. In this example, the T/H can operate at sample rate f_(s) (or the full-speed of the time-interleaved ADC), while each slice can operate operating at a slower rate, such as f_(s)/M. The output of the T/H circuit 104 is a held signal, and each slice is driven by the same held signal. Therefore, the effect of timing and bandwidth (BW) mismatches between the slices can be eliminated.

A fast T/H circuit can be non-trivial to design. High speed T/H circuits can, in some cases, suffer from very high power consumption, high noise, and low performance. The choice to use a faster T/H circuit to drive multiple ADC slices is a deliberate decision between what to optimize in the analog circuit and what to fix with calibration. Since timing and/or bandwidth mismatch is difficult to address, the T/H circuit and the rest of the ADC can be designed to avoid timing and/or bandwidth mismatch problems. Gain and offset mismatches can be more compatible with calibration. Various T/H circuits described herein were designed to facilitate digital calibration of gain and offset mismatches while avoid timing and bandwidth mismatch problems through deliberate analog circuit design.

Herein, the implementations of the T/H circuits are illustrated in single-ended form. In practice, the T/H circuits can be implemented differentially to suppress possible even-order harmonics.

Improved Track and Hold Circuits Allowing Dither Injection

Because a full-speed T/H circuit can be complex and power hungry, certain design decisions were made to ensure the T/H circuit can achieve target performance while not consuming too much power. One way to achieve better performance out of a circuit is to use calibration to linearize the T/H circuit. To allow for calibration, the T/H circuit is designed to incorporate the injection of additive and multiplicative dither into the T/H circuit to enable the calibration of the circuitry downstream from where the dither is injected.

For instance, the calibration of the circuitry can include extracting and calibrating for the non-idealities in the T/H circuit based on the additive dither and/or multiplicative dither. Furthermore, calibration can include extracting and calibrating the offset and gain mismatches between the slices. For instance, adding pseudo-random signal (dither) to the input signal enables the calibration of gain mismatch in time-interleaved ADCs. In addition, the dither can be used to calibrate the T/H circuit non-linearity and ADC non-linearity. Advantageously, additive dither in the T/H circuit can:

Enable non-linear calibration of the T/H circuit's hold phase non-linearity:

-   -   Lower power in T/H circuit,     -   Better second harmonic (HD2) and third harmonic (HD3)         performance, and     -   Simpler switches=>lower power in clocking,

Enable non-linear calibration of the ADC slices' non-linearity:

-   -   Lower power in the ADC slices (e.g., reference buffer,         amplifiers, etc.),     -   Lower power in the clocking and switching, and     -   Better HD2, HD3 performance in the ADC slices',

Enable interleaving gain mismatch calibration in the ADC slices:

-   -   Insensitive to the presence of input signal,     -   Insensitive to the input signal frequency,     -   More robust calibration, and

Dither the hold phase spurs.

Furthermore, multiplicative dither (e.g., random chopping) can be used to calibrate offsets and offset mismatches. Advantageously, multiplicative dither in the T/H circuit can:

Enable robust calibration of offset mismatch between the ADC slices:

-   -   Independent of the input signal, and     -   Insensitive to “bad” frequencies (e.g., f_(s)/M, M is the number         of ADC slices),

Protect the direct current (DC) input from being zeroed out,

Dither any remaining offsets, flicker noise, offset mismatch, thermal drifts, etc., and

Obviate the need for core randomization for offset mismatch.

The additive dither can be injected to correct for one or more of the following: calibration of non-linearity, calibration of memory effects, calibration of chopping non-idealities, calibration of gain error, calibration of gain mismatch in interleaved ADCs, and calibration of track/sampling memory. The multiplicative dither can be used for one or more of the following: correct for offset mismatch and correct for even-order distortion.

FIG. 2 shows an exemplary T/H circuit 200 having two buffers, Buffer-1 202, and Buffer-2 206 and a switched-capacitor network 204 in between the two buffers, according to some embodiments of the disclosure. Dither can be injected in the switched-capacitor network 204, and the dither can be used to calibrate the Buffer-2 206 and the ADC following the T/H circuit 200. As mentioned before, the dither can be an additive dither or a multiplicative dither. The Buffer-1 202 receives the (voltage) input V_(in), and buffers the input. The buffered input can be sampled on the switched-capacitor network 204. For instance, the switched-capacitor network 204 can sample the buffered input onto capacitor using suitable switches. The buffer-206 can buffer the sampled input and provided the held signal V_(s-h) to an ADC (not shown in FIG. 2).

The T/H circuit 200 can be seen as an open loop T/H circuit. The switched-capacitor network 204 can be a sampling network. Buffer-1 202 can be a sampling buffer, and Buffer-2 206 can be a hold buffer. The buffers are optional, and can be included to provide isolation between different circuit stages. The buffers can be source followers, emitter followers, push pull topology, or any other suitable buffer structure. Buffer-1 202 can be optimized for sampling linearity. Buffer-2 206 can be optimized for low-power, small size, small input capacitance, and good isolation. Isolation for Buffer-2 206 can help reduce input-referred noise of the ADC which follows the T/H circuit 200. The linearity of Buffer-2 206 is not as critical as the linearity of Buffer-1 202 because Buffer-2 206 handles and buffers a held signal. In addition, since dither is injected in the switched-capacitor network 204, the non-linearity of the Buffer-2 206 can be calibrated, which helps further lower the power and size of Buffer-2 206. In addition, the gain and offset mismatches between the ADC slices driven by the T/H circuit can be calibrated by injecting a dither in the switched-capacitor network 204. Different gains of the ADC slices can be measured easily with a dither injected in the shared T/H circuit 200 driving the ADC slices.

One insight of the three-part circuit design of the T/H circuit comes from realizing how to reduce the power consumption of a T/H circuit that has to drive M ADC slices. In the past, an input buffer has to drive M ADC slices, and an input buffer has to be very linear and is likely to consume a lot of power. With the three-part circuit design seen in FIG. 2, the sampling buffer (Buffer-1 202) only needs to drive one sampling network (or, in some cases, 2 to 4 sampling networks depending on the implementation). The (capacitive) load on the sampling buffer can be smaller, and therefore the sampling buffer can consume less power while achieving comparable or better performance, even if the sampling buffer has sample a radio frequency (RF) or high frequency signal. The hold buffer (Buffer-2 206) is driving a held signal, and any problems with the hold buffer can be more benign. The primary requirement for the hold buffer is how well the output of the hold buffer settles. Also, the hold buffer has no input frequency sensitivity. Even though the hold buffer may have to drive M ADC slices, the linearity of the hold buffer is not extremely critical since the hold buffer can be calibrated with the dither being injected in the sampling network. Therefore, power savings can still be achieved.

Track and Hold Circuit with Amplification

Typically for high speed ADCs, amplification is not available in the input circuitry because open loop amplification can be very non-linear. FIG. 3 shows an exemplary T/H circuit 300 having a buffer 302, a switched-capacitor network 204, and an amplifier 304, according to some embodiments of the disclosure. Comparing the T/H circuit 300 with the T/H circuit 200 of FIG. 2, buffer 302 can be similar to Buffer-1 202, but Buffer-2 206 is replaced by amplifier 304. Since the amplifier 304 can be an open loop amplifier, amplifier 304 is likely to suffer from poor linearity. By virtue of having dither injection in the switched-capacitor network 204, the amplifier 304 can be calibrated and any possible non-linearities associated with the amplifier 304 can be addressed. The ability to provide amplification in the T/H circuit 300 is advantageous since it greatly relaxes the requirements on the input signal being provided to the T/H circuit 300. Besides, the amplifier 304 can, just like the Buffer-2 206 of FIG. 2, reduce input-referred noise of the ADC which follows the T/H circuit 300.

Besides providing amplification, the amplifier 304 can be a VGA or provide variable gain. The gain can be varied based on one or more conditions and/or set by one or more specified parameters. A gain control signal “GAIN” can be used to vary the gain provided by amplifier 304. In some embodiments, a signal level detector 306 can be implemented to generate the gain control signal “GAIN” to control the amplifier 304 based on signal level conditions. For instance, if the signal level detector 306 detects an overload condition (e.g., a very large input signal V_(in)), the signal level detector 306 can generate an appropriate gain control signal “GAIN” to reduce the gain of the amplifier 304.

Although not shown as an amplifier, buffer 302 can be implemented as an amplifier in some cases. The amplifier in place of buffer 302 can be a variable gain amplifier (e.g., controllable by signal level detector 306). Depending on the implementation, the amplifier is an open loop amplifier, or a closed loop amplifier. A closed loop amplifier may be preferred since they can be more accurate than an open loop amplifier. In some cases, buffer 302 can be preceded by a separate amplifier (open loop or closed loop). Amplification at the sampling side can also relax the requirements on the input signal being provided to the T/H circuit 300.

It is understood that the various embodiments shown herein with a hold buffer such as “Buffer-2” can be replaced with an amplifier 304 as illustrated by FIG. 3.

Sampling Network with Dither Injection

Dither can be injected into a node of the switched-capacitor network of the T/H circuit through different circuit topologies described herein. A dither is a random signal. A dither can have different levels. In one example, a dither can be generated by a digital-to-analog converter receiving a digital input (the dither in digital form) and generating an analog output (the dither in analog form). The analog output from the digital-to-analog converter can be injected into the switched-capacitor network of a T/H circuit. In some cases, a dither can randomly change between positive or negative (e.g., randomly changing between +1, and −1, or +V or −V where V is a nominal value). The type of dither being injected can differ depending on the desired calibration to be performed or effect to be achieved.

FIG. 4 shows an exemplary T/H circuit 400 illustrating one exemplary switched-capacitor network with sampling and dither injection, according to some embodiments of the disclosure. Dither is injected in the switched-capacitor network at node V_(R) and can be used to calibrate Buffer-2 206 and the ADC following the T/H circuit 400. The switched-capacitor network has capacitor C 402 for sampling the input, an input switch 404 for receiving the (buffered) input from Buffer-1 202, a sampling switch 406, and a dither injection switch 408. In the FIGURES, various phase ϕ symbols adjacent to the switches indicate a phase or timing indicating when a given switch is closed. Top and bottom plates of capacitor C is indicated as “t” and “b” respectively.

During sampling phase, the input switch 404 having phase ϕ1_btst and the sampling switch 406 having phase ϕ1 a are closed. The input switch 404 can be a bootstrapped switch (i.e., bootstrapped to the buffered input) to achieve good linearity. The sampling switch having ϕ1 a 406 is advanced (opens before the input switch 404 is opened) to achieve bottom plate sampling. The dither injection switch 408 having phase ϕ2 is opened during the sampling phase. At the end of the sampling phase, the input signal is sampled onto capacitor C 402.

During a hold phase, both the input switch 404 having phase ϕ1_btst and the sampling switch 406 having phase ϕ1 a are opened. Dither injection switch 408 having phase ϕ2 closes to connect the top plate of the capacitor C 402 to the node V_(R). Accordingly, additive dither can be injected in the switched-capacitor network. The T/H circuit 400 holds the sampled voltage (the sampled input signal), plus the additive dither injected, at the output as V_(s-h). In this embodiment, the output bias point of Buffer-1 202 does not need to be compatible with the input bias point of Buffer-2 206. The output V_(s-h) in FIG. 4 is an inverted version of the input V_(in) plus the additive dither injected at node V_(R).

FIG. 5 shows an exemplary T/H circuit 500 illustrating another exemplary switched-capacitor network with sampling and dither injection, according to some embodiments of the disclosure. Similar to FIG. 4, additive dither is injected in the switched-capacitor network and can be used to calibrate Buffer-2 206 and the ADC following the T/H circuit 500. The switched-capacitor network has capacitor C 502 for sampling the input, an input switch 504 for receiving the (buffered) input from Buffer-1 202, a sampling switch 510, a dither injection switch 508, and an output switch 506.

During sampling phase, the input switch 504 having phase ϕ1_btst and the sampling switch 510 having phase ϕ1 a are closed. The input switch 504 can be a bootstrapped switch (i.e., bootstrapped to the buffered input) to achieve good linearity. The sampling switch 510 having ϕ1 a is advanced (opens before the input switch 504 is opened) to achieve bottom plate sampling. The dither injection switch 508 having phase ϕ2 and the output switch 506 having phase ϕ1_btst are opened during the sampling phase. At the end of the sampling phase, the input signal is sampled onto capacitor C 502.

During a hold phase, both the input switch 504 having phase ϕ1_btst and the sampling switch 510 having phase ϕ1 a are opened. Dither injection switch 508 having phase ϕ2 closes to connect the bottom plate of the capacitor C 502 to the node V_(R). Accordingly, additive dither can be injected in the switched-capacitor network. Output switch 506 having phase ϕ2_btst also closes to connect the capacitor C 502 to the Buffer-2 206. The output switch 506 can optionally be a bootstrapped switch to achieve good linearity. The T/H circuit 500 holds the sampled voltage (the sampled input signal), plus the additive dither injected, at the output as V_(s-h). In this embodiment, the output bias point of Buffer-1 202 is preferably compatible with the input bias point of Buffer-2 206. The output V_(s-h) is a non-inverted version of the input V_(in) plus the additive dither injected at node V_(R).

Compared to the T/H circuit 400 in FIG. 4, the T/H circuit 500 can have two bootstrapped switches, which can be more complicated and expensive. However, having the two bootstrapped switches can provide better isolation, and can enable using more than one sampling network (e.g., more than one switched-cap network sampling in an interleaved fashion) with the same Buffer-2 206, if needed, to achieve higher speeds.

Output switch 506 does not have to be bootstrapped, since the dither being injected can be used to calibrate output switch 506. If indeed the output switch 506 is bootstrapped, then calibration may not be needed since the output switch 506 is linear enough. If the output switch 506 is not bootstrapped (e.g., just boosted), then calibration can be used to address non-linearities of the output switch 506.

FIG. 6 shows an exemplary T/H circuit 600 illustrating yet another exemplary switched-capacitor network with sampling and dither injection, according to some embodiments of the disclosure. Dither is injected in the switched-capacitor network and can be used to calibrate Buffer-2 206 and the ADC following the T/H circuit 600. The switched-capacitor network has capacitor C 602 for sampling the input, an input switch 604 for receiving the (buffered) input from Buffer-1 202, a sampling switch 606, a dither injection switch 608, and an output switch 610. The T/H circuit 600 can be seen as a mix of the T/H circuit 400 of FIG. 4 and T/H circuit 500 of FIG. 5. The sampling is done in a manner similar to FIG. 4, but an additional switch (i.e., the output switch 610) is present in series with the capacitor C 602 to connect the capacitor C 602 during the hold phase and isolate the switched-capacitor network from the Buffer-2 206.

During sampling phase, the input switch 604 having phase ϕ1_btst and the sampling switch 606 having phase ϕ1 a are closed. The input switch 604 can be a bootstrapped switch to achieve good linearity. The sampling switch having ϕ1 a 606 is advanced (opens before the input switch 604 is opened) to achieve bottom plate sampling. The dither injection switch 608 having phase ϕ2 and the output switch having phase ϕ2 are opened during the sampling phase. At the end of the sampling phase, the input signal is sampled onto capacitor C 602.

During a hold phase, both the input switch 604 having phase ϕ1_btst and the sampling switch 606 having phase ϕ1 a are opened. Dither injection switch 608 having phase ϕ2 closes to connect the top plate of the capacitor C 602 to the node V_(R). Accordingly, additive dither can be injected in the switched-capacitor network. Output switch 610 having phase ϕ2 also closes to connect the capacitor C 502 to the Buffer-2 206. In some cases, the output switch 610 can be a bootstrapped switch to achieve good linearity. In some cases, the output switch is not bootstrapped. Bootstrapping the output switch 610 is less critical in this case since the output switch 610 can be calibrated using the additive dither being injected. The T/H circuit 600 holds the sampled voltage (the sampled input signal), plus the additive dither injected, at the output as V_(s-h). In this embodiment, the output bias point of Buffer-1 202 does not need to be compatible with the input bias point of Buffer-2 206. The output V_(s-h) is an inverted version of the input V_(in) plus the additive dither injected at node V_(R).

Track and Hold Circuits with Multiple Hold Buffers

The T/H circuit can be adapted to drive multiple ADCs. For instance, instead of having a single hold buffer (i.e., Buffer-2 206 of the various FIGURES) driving multiple ADCs, the T/H circuit can duplicate the hold buffer, and the hold buffers can then drive respective ADCs. FIG. 7 shows an exemplary T/H circuit 700 with multiple hold buffers, shown as Buffer-2 702 ₁, Buffer-2 702 ₂, . . . Buffer-2 702 _(M), according to some embodiments of the disclosure. Similar to other T/H circuits described herein, the T/H circuit 700 has a sampling buffer Buffer-1 202 and a switched-capacitor network 204. Rather than having just one hold buffer, M hold buffers can be implemented in T/H circuit 700 to drive M ADCs. Each one of the hold buffers can generate a respective output signal V_(s-h1), V_(s-h2), . . . V_(s-hM), and drive a respective ADC. Since the hold buffer no longer has to drive multiple ADCs, the Buffer-2 702 ₁, Buffer-2 702 ₂, . . . Buffer-2 702 _(M) can be smaller in size than a single hold buffer driving multiple ADCs. In other words, not having to drive multiple ADCs using a single hold buffer can relax the requirements on the hold buffer. Moreover, the hold buffer can be calibrated using the dither being injected into the sampling network. So, the requirements on the hold buffer may be relaxed further due to calibration. Furthermore, having multiple hold buffers can help the T/H circuit 700 have better isolation between the different slices.

In an alternative implementation, the T/H circuit 700 can be adapted to duplicate the sampling network as well. A sampling network per hold buffer can be implemented. For instance, such adapted T/H circuit driving M ADCs can include a sampling buffer, M switched-capacitor networks, and M hold buffers.

Track and Hold Circuits with Time-Interleaved Sampling Networks

If it is difficult to implement a full-speed sampling network to sample the input signal, the T/H circuit can be adapted to implement time-interleaving. Rather than having a single switched-capacitor network to sample the input signal, multiple sampling networks can be implemented in the T/H circuit and interleaved in time. FIG. 8A shows an exemplary T/H circuit 800 with multiple sampling networks, shown as sampling network 802 and sampling network 804, according to some embodiments of the disclosure. The T/H circuit 800 has a Buffer-1 202, sampling network 802 and sampling network 804, and a Buffer-2 206. The sampling network 802 and sampling network 804 as shown has the circuit topology illustrated in FIG. 5, however, other circuit topologies for the sampling networks 802 and 804 (e.g., one shown in FIG. 6) can be used. The circuit topology of the sampling network illustrated in FIG. 4 without the output switch can also be used, but the T/H circuit may need to duplicate hold buffers as well. The circuit topologies of the sampling network in FIGS. 5 and 6 having the output switch may obviate the need to have multiple hold buffers.

In this example, the sampling network 802 and the sampling network 804 can ping-pong with each other, sampling the (buffered) input signal one after another in a time-interleaved manner. FIG. 8B illustrates timing for the T/H circuit 800 of FIG. 8A, according to some embodiments of the disclosure. Clock (plot 880) illustrates the full-speed clock at frequency f_(s), having a period T_(s). As seen in the timing diagram, an interleaved sampling network (e.g., sampling network 802 and sampling network 804) can run at a frequency of f_(s)/2. T/H-1 (plot 882) illustrates the phases of sampling network 802; T/H-2 (plot 884) illustrates the phases of sampling network 804. During the first period of the full-speed clock, the sampling network 802 is in a sampling phase, and the sampling network 804 is in a hold phase. Switches associated with ϕ1 (e.g., ϕ1_btst and ϕ1 a) in FIG. 8A can be closed accordingly for both sampling networks. Switches associated with ϕ2 (e.g., ϕ2_btst and ϕ2 a) in FIG. 8A can be open accordingly for both sampling networks. During the second period, the sampling network 802 proceeds to a hold phase, and the sampling network 804 goes to a sampling phase. Switches associated with ϕ2 (e.g., ϕ2_btst and ϕ2 a) in FIG. 8A can be closed accordingly for both sampling networks. Switches associated with ϕ1 (e.g., ϕ1_btst and ϕ1 a) in FIG. 8A can be open accordingly for both sampling networks. During the third period, the sampling network 802 returns to a sampling phase, and the sampling network 804 proceeds to a hold phase. Switches associated with ϕ1 (e.g., ϕ1_btst and ϕ1 a) in FIG. 8A can be closed accordingly for both sampling networks. Switches associated with ϕ2 (e.g., ϕ2_btst and ϕ2 a) in FIG. 8A can be open accordingly for both sampling networks. The ping-pong behavior can repeat over time (e.g., over many periods).

With time-interleaved sampling networks, the speed of a single sampling network can be significantly reduced. For instance, sampling network 802 and sampling network 804 would only need to sample the input at half the full-speed of the T/H circuit 800. While two sampling networks are shown, it is appreciated that more than two sampling networks can be time-interleaved or included in the T/H circuit, depending on the desired order of interleaving for the application.

While FIG. 8A illustrates a single hold buffer, it is possible to have a dedicated hold buffer per sampling network. In such a case, if the M ADC slices are operating in a sequential time-interleaved manner, each buffer can drive just M/2 ADC slices.

With time-interleaved sampling networks, the T/H circuit can be exposed to mismatches between the sampling networks. For instance, mismatches between the switches enabling bottom plate sampling can contribute to sampling performance degradation if they are not addressed. Specifically, those mismatches can create undesirable spurs in the output. Unfortunately, the dither cannot help with calibrating such mismatches. To address such mismatches, an additional sampling network can be added to enable randomization. FIG. 9 shows another exemplary T/H circuit 900 with multiple sampling networks, according to some embodiments of the disclosure. Three sampling networks are shown, and it is appreciated that other higher number of sampling networks can be implemented. For this example, at any given period, two sampling networks may be available for sampling the input. One of the two sampling networks can be selected to sample the input at random. Randomizing the sampling network selection (e.g., where the sampling networks sample the buffered input in a randomized time-interleaved manner) can randomize the mismatches between the sampling networks, and push the tones from the mismatches towards the noise floor.

In general, randomization can be enabled by adding one or more additional sampling networks than the minimum number of sampling networks desired for achieving the desired sampling rate. Suppose two sampling networks is needed to achieve the desired sampling rate, adding one (or more) sampling networks can allow for randomization.

In some embodiments, adding more sampling networks can enable higher order time-interleaving, or more functions. For instance, more randomization can be introduced by providing more sampling networks, making more sampling networks available for selection at a given period.

In some cases, a fourth or further sampling network can be added to enable the resetting of each network after its hold phase and before being ready for the next sampling phase. In other words, a sampling network proceeds to a reset phase after the hold phase to allow the circuits to clear (a sampling network may need three periods rather than just two periods before it can sample the input again). By adding an additional sampling network, more time is allowed for resetting the sampling capacitor(s). Effectively, the sampling capacitor(s) within a sampling network that just finished its hold phase can be reset fully to reset any memory in the sampling capacitor(s). The memory can be present on sampling capacitor(s) when switching between the hold phase back to the sampling phase, if additional reset time/phase is not provided for the sampling capacitor(s). If an additional sampling network is provided to allow for resetting, at a given point in time, two sampling networks are busy, one sampling network can be ready to be used or selected at the next period, and one sampling network can be in the reset phase so that it can be used or selected at the next period after the sampling network is reset.

FIG. 10 shows yet another exemplary T/H circuit 1000 with multiple sampling networks, according to some embodiments of the disclosure. As seen in FIG. 10, an additional (fourth) sampling network is provided to ensure there is at least two available sampling networks to select from at a given period to be the next sampling network to sample the input. Having an additional sampling network allows a given sampling network to take an additional period to reset before the given sampling network has to sample the input again. Providing the additional reset phase can help to get reduce or address the memory effects and/or order-dependent effects that can be detrimental to the performance of the T/H circuit, especially when randomization is employed.

In some cases, the time-interleaving sampling networks of a T/H circuit can be configured to operate in different modes of operation. For instance, the clocking of the switches in the sampling networks can be controlled differently depending on the specified mode. The sampling networks can operate in a sequential mode or a randomized mode. The sampling network can operate in a mode that requires a reset phase or in a mode that does not require a reset phase. The desired mode can be specified by one or more user-provided signals, or one or more signals from circuitry suitable for setting the mode.

FIG. 11 shows an exemplary T/H circuit 1100 with multiple time-interleaved sampling networks (seen as sampling networks 1102, 1104, and 1106) and a single hold buffer, according to some embodiments of the disclosure. As an example, implementation for three sampling networks of FIG. 9 is shown, based on the circuit topology of the sampling network seen in FIG. 5. It is appreciated that the circuit topology of the sampling network seen in FIG. 6 can also be used as the sampling networks of T/H circuit 1100. To use a single hold buffer, it is preferable for each sampling network to include an output switch. In this case, the output switch in the sampling networks (labeled as S2 switches with respective phases ϕ1_bst, ϕ2_bst, and ϕ12_bst in FIG. 11) does not have to be a bootstrapped switch. Rather, it can be a simpler boosted switch instead (e.g., a transmission gate). The output switches can be calibrated using the dither injected in the sampling network, and therefore the design requirements on the analog circuit of the output switches can be relaxed. For this particular example shown, the sampling networks sample the buffered input from Buffer-1 202 in a randomized time-interleaved manner. In other words, one out of two available sampling networks can be randomly selected to be the next sampling network to sample the input to randomize mismatch errors between the sampling networks. The circuit design shown in FIG. 11 can be extended to higher number of sampling networks.

In some embodiments, rather than having a single hold buffer as seen in FIGS. 9-11, multiple hold buffers can be included in the T/H circuit with time-interleaved sampling networks. FIG. 12 shows an exemplary T/H circuit 1200 with multiple time-interleaved sampling networks and multiple hold buffers, according to some embodiments of the disclosure. The Having multiple hold buffers can provide better isolation between slices, and can reduce design requirements imposed on the individual hold buffers (with similar benefits as the example seen in FIG. 7). In this particular example, the T/H circuit has a sampling buffer 202, three sampling networks (shown as sampling networks 1202, 1204, and 1206), and three hold buffers (shown as Buffer-2 1208, Buffer-2 1210, and Buffer-2 1212). Each sampling network has a dedicated hold buffer to drive the ADC which follows the hold buffer. The hold buffers (Buffer-2 1208, Buffer-2 1210, and Buffer-2 1212) receive respective held signals from sampling networks (shown as sampling networks 1202, 1204, and 1206). With a dedicated hold buffer, the sampling networks can avoid having an output switch, if desired. Each one of the hold buffers can generate a respective output signal (shown as V_(s-h1), V_(s-h2), and V_(s-h3)) and drive a respective ADC.

For this particular example shown, two sampling networks can be randomly selected to be the next sampling network to sample the input to randomize mismatch errors between the sampling networks. The circuit design shown in FIG. 12 can be extended to higher number of sampling networks, each with a dedicated hold buffer.

One caveat of the randomized time-interleaving design illustrated by FIG. 12 having multiple dedicated hold buffers is that each dedicated hold buffer would have to drive M ADC slices, which can consume more power than a T/H circuit which performs sequential time-interleaving (where the dedicated hold buffer would only need to drive a fraction of the M ADC slices).

Track and Hold Circuits with Chopping

In addition to injecting additive dither, the T/H circuit can randomly chop the input signal by randomly changing polarities based on a pseudo-random code “PN”. In other words, the T/H circuit can have multiplicative dither injected, where the dither can be a +1 or −1, as chosen by the code PN. FIG. 13A illustrates a T/H circuit 1300 with chopping to inject a multiplicative dither, according to some embodiments of the disclosure. A chopper 1302 performing a chopping function can be integrated with a switch in the sampling network, such as the input switch, or the output switch. To illustrate, the chopper 1302 is added to the embodiment seen in FIG. 5. The chopper 1302 can be added to other sampling networks described herein. While the chopper 1302 in this example seen in FIG. 13A is added/integrated with the output switch (e.g., output switch 506), it is envisioned that the chopper can be added/integrated with the input switch (e.g., input switch 504). The chopper 1302 can be integrated with the output switch (e.g., output switch 506) to inject the multiplicative dither.

FIG. 13B illustrates integrating the chopper 1302 with a switch in the sampling network, according to some embodiments of the disclosure. Mathematically, the chopper 1302 multiplies the signal with a dither represented by −1^(PN), where PN is a pseudo-random code. For illustration, on the left hand side of FIG. 13B, an output switch S2 associated with phase ϕ2_bst is shown, followed with a chopping function represented by chopper 1302. This chopping function can be achieved in a differential circuit implementation seen on the right hand side of FIG. 13B. In a differential circuit, the node V1 on the left hand side of FIG. 13B is represented by differential nodes V1 p and V1 n respectively on the right hand side of FIG. 13B. The node V2 on the left hand side of FIG. 13B is represented by differential nodes V2 p and V2 n respectively on the right hand side of FIG. 13B. The circuit seen on the right hand side of FIG. 13B has straight forward paths and crisscross paths. The switches in these paths enables random switching between the straight forward paths and crisscross paths. The straight forward paths with switches associated with ϕ2_bst*PN allows the differential signal at nodes V1 p and V1 n to pass straight through to nodes V2 p and V2 n respectively. The crisscross paths with switches associated with ϕ2_bst*PN′ (where PN′ is the inverted PN) invert the differential signal at nodes V1 p and V1 n and pass the differential signal to nodes V2 n and V2 p respectively. In other words, the multiplicative dither PN can randomly swap positive and negative input paths. By randomly swap positive and negative input paths, the circuit seen in the right hand side of FIG. 13B effectively implements the chopping function and multiplies the signal by +1 or −1 randomly.

By randomly swapping the positive and negative input paths, the DC (direct current) component of the input signal can be randomized, making it easier to calibrate for any offset mismatches between the different slices. The chopping function can be implemented with the input switch of the sampling network, which can randomly invert the signal in the sampling phase. The chopping function can be implemented with the output switch, which can randomly invert the signal in the hold phase. In some cases, the chopping function can be implemented with both the input switch and the output switch using different PN codes.

FIG. 14 illustrates another exemplary T/H circuit 1400 with chopping to inject a multiplicative dither, according to some embodiments of the disclosure. A chopper 1402 performing a chopping function can be integrated with a switch in the sampling network, such as the input switch, or the output switch. To illustrate, the chopper 1402 is added to the embodiment seen in FIG. 6. The chopper 1402 can be added to other sampling networks described herein. While the chopper 1402 in this example seen in FIG. 14 is added/integrated with the output switch (e.g., output switch 610), it is envisioned that the chopper can be added/integrated with the input switch (e.g., input switch 604). The chopper 1402 can be integrated with the output switch (e.g., output switch 506) to inject the multiplicative dither.

FIG. 15 shows an exemplary T/H circuit 1500 with multiple sampling networks with chopping added to inject a multiplicative dither, according to some embodiments of the disclosure. Chopping is added to the exemplary T/H circuit 1100 of FIG. 11. Specifically, as an example, the chopping function is integrated with the output switches labeled S2 associated with ϕ1_bst, ϕ2_bst, and ϕ12_bst. In the alternative, the chopping function can be integrated with the input switches labeled 51 associated with ϕ2_btst, ϕ1_btst, and ϕ21_btst. The former has the additional advantage that the chopper can be calibrated by the additive dither if desired. This chopping can then be reapplied on the digital side after offset calibration to restore the original signal.

FIG. 16 shows another exemplary T/H circuit 1600 with multiple sampling networks with chopping added to inject a multiplicative dither, according to some embodiments of the disclosure. Specifically, as an example, the chopping function is integrated with the output switches labeled S2 associated with ϕ1_bst, ϕ2_bst, and ϕ12_bst. In the alternative, the chopping function can be integrated with the input switches labeled 51 associated with ϕ2_btst, ϕ1_btst, and ϕ21_btst. The former has the additional advantage that the chopper can be calibrated by the additive dither if desired. This chopping can then be reapplied on the digital side after offset calibration to restore the original signal.

Chopping can be useful for offset mismatch calibration, where the chopping function can converts any input offset and/or signals at problematic frequencies (such as f_(s)/M, and f_(s)/2M, where M is the number of slices) into noise, e.g., so as to not impact the offset convergence and removal of the offset. Chopping can also help with even-order distortions or to reduce even-order harmonics in the signal path. It is understood that while the chopping function can be integrated with a switch that is in the sampling network, it is possible to include/integrate a chopper at any point in the signal path, such as at the output of Buffer-1 202.

Handling Output Routing Parasitics and Load on the Track and Hold Circuit

Driving M ADC slices is not trivial. Suitable switches and switching scheme can address parasitics and loading effects on the T/H circuit. Consider driving 8 ADC slices in the following example. FIG. 17A shows an exemplary T/H circuit driving 8 slices, according to some embodiments of the disclosure. For each signal path from the T/H circuit to an ADC slice, two serial switches are implemented to manage the parasitics and load on the track and hold circuit. The first set of switches are labeled “SW-A”, and they are positioned close to the output of Buffer-2. The second set of switches are labeled “SW-B”, and they are positioned close to the input of the ADC slices. A SW-A switch, when on or closed, couples an output of the Buffer-2 206 to a SW-B switch (or transmits/conducts the signal from the output of the Buffer-2 206) to a terminal of the SW-B switch). The SW-B switch, when on or closed, couples the SW-A switch to an input of an ADC slice (or transmits/conducts a signal at a terminal of the SW-A switch to the input of the ADC slice). The two serial switches, SW-A and SW-B, can be separated by a transmission line or wire of a certain length for routing the buffered signal from Buffer-2 206 to the respective ADC slices.

A timing diagram in FIG. 17B illustrates the timing of a SW-A switch and a SW-B switch for a particular ADC slice when the ADC slice is selected to perform conversion. The SW-A switch, whose timing is illustrated in the timing diagram in FIG. 17B, is turned on quickly and turned off quickly at the fast rate of f_(s) (the overall sampling frequency of the data converter). In other words, the SW-A switch is turned on with a short pulse, since the SW-A switch hands off data from the fast (full-speed) T/H circuit to a slow ADC slice. The SW-B switch, whose timing is also illustrated in the timing diagram above, can operate at a slower speed. A SW-B switch can be on before SW-A switch is turned on, and can turn off at the same time or just after SW-A switch is turned off. The switches can be simple transmission gates (not bootstrapped switches), thus the penalty of having both switches is not significant.

The SW-A switch is placed close (in layout) to the T/H circuit, and can help minimize the parasitic loading effect on the Buffer-2 caused by the slices which are not connected to the T/H circuit. Since the SW-A switch is not close to the ADC slice, the load on the ADC slice is left unaddressed in the absence of the SW-B switch. The SW-B switch is placed close (in layout) to the ADC slice, and can help reduce the load on the T/H circuit by connecting the T/H circuit to one ADC slice at a time. SW-B minimizes the routing seen by the ADC slice and the T/H circuit when resetting. Therefore, SW-B can minimize the parasitics needed for resetting this node when it is not being used. By using two serial switches and proper timing, SW-A and SW-B switches ensure that whenever a selected ADC slice is connected to the T/H circuit to receive a held sample, only the parasitics of the selected ADC slice is loading the Buffer-2 206 of the T/H circuit (all the other ADC slices are disconnected from the Buffer-2 206). Together, the SW-A and the SW-B switch can help reduce routing parasitics load on the T/H circuit and on the selected ADC slice.

It is preferable to use both SW-A and SW-B switches for each signal path from the T/H circuit to the ADC slice. It is envisioned that one of the two switches can be omitted, in some less preferred embodiments. For instance, in some cases, only the SW-A switches are provided, while the SW-B switches are omitted.

Addressing Common Memory in Time-Interleaved Sampling Networks

When parallel sampling networks are time-interleaved, some common memory at a global input node of the sampling networks can be present between a hold phase to a sample phase. This common memory can be seen by all of the sampling networks, and this common memory is not the same as the memory within the sampling capacitor(s) addressed by adding a reset phase. To address the common memory issue, clock signals driving the switches in the sampling network can overlap to allow for to allow for brief resetting of the global input node.

The overlap in the clock signals is between the bottom plate sampling switch, and the dither injection switch and the output switch (labeled “S2”). It can be that the output switch closes before the bottom plate sampling switch is opened, or the bottom plate sampling switch closes before the output switch is opened. The latter case is preferred, because the former case can impact the sampled value on the cap, but both are viable.

Referring to FIGS. 15 and 16, the overlapping would occur between clock signals associated with phase ϕ1/ϕ1_bst (including the dither injection switch and the output switch), and ϕ2 a (including the bottom plate sampling switch) for the top sampling network. Overlapping would also occur between clock signals associated with phase ϕ2/ϕ2_bst (including the dither injection switch and the output switch), and ϕ1 a (including the bottom plate sampling switch) for the middle sampling network. The overlapping would occur between clock signals associated with phase ϕ12/ϕ12_bst (including the dither injection switch and the output switch), and ϕ21 a (including the bottom plate sampling switch) for the bottom sampling network as well.

Focusing on the top sampling network as an example, the overlap can mean that either (1) ϕ1/ϕ1_bst close the dither injection switch and output switch before ϕ2 a opens the bottom plate sampling switch, or (2) ϕ2 a closes the bottom plate sampling switch before ϕ1/ϕ1_bst open the dither injection switch and output switch. The latter is again better, because the former would possibly negatively impact the sample before it is taken. But both are viable.

Phrased differently, the overlap preferably happens at the end of the hold phase and beginning of sampling phase (when the bottom plate sampling switch closes), and is less preferred at the end of the sampling phase and beginning of the hold phase (when the dither injection switch and the output switch close). This overlap can help reset this global input node to reduce the common memory that is seen by all tracks.

Flexible Architecture

The design and implementation of the T/H circuit can be varied to accommodate different functionalities and features. The number of sampling networks, the number of hold buffers, and the number of ADC slices that a hold buffer is driving, can all vary.

As discussed previously, the T/H circuit can include one or more sampling networks in parallel. The number of sampling networks within the T/H circuit can vary depending on the design. For instance, the number can be chosen based on the interleaving factor and amount of randomization. For example, a T/H circuit can have one sampling network and one hold buffer (e.g., FIGS. 2-6). In another example, a T/H circuit can have one sampling network and X number of hold buffers (e.g., FIG. 7). X is at least two. In yet another example, a T/H circuit can have X number of sampling networks and one hold buffer (e.g., FIGS. 8A, 9-11, 15, 16, and 17A). In a further example, a T/H circuit can have X number of sampling networks and X number of hold buffers (e.g., FIG. 12).

Also, the T/H circuit can include one or more hold buffers. In some cases, there is one buffer to one sampling network. For example, the T/H circuit can have one sampling network, and the sampling network drives one hold buffer (e.g., FIGS. 2-6). In another example, the T/H circuit can have X number of sampling networks and X number of hold buffers (e.g., FIG. 12). In some cases, there is multiple buffers to one sampling network. For example, the T/H circuit can have one sampling network, and X number of hold buffers (e.g., FIG. 7). In another example, the T/H circuit can have X number of sampling networks, and X*N number of hold buffers. N is at least two, representing the number of hold buffers per sampling network. If a T/H circuit has four sampling networks, there can be eight hold buffers in total, with two hold buffers per sampling network. In yet another example, the T/H circuit can have X number of sampling networks, and Y number of hold buffers, where Y is greater than X. Each sampling network can drive one or more hold buffers (where the number of hold buffers for each sampling network may not be the same).

Furthermore, the T/H circuit can drive one or more ADC slices. The ADC slices can operate in parallel, and in some cases, the ADC slices can operate in a time-interleaved or a randomized time-interleaved manner. For example, a T/H circuit can drive one ADC slice. In another example, the T/H circuit can drive M ADC slices (e.g., FIGS. 1 and 17A). M is at least two, representing the number of ADC slices of the overall ADC. If the T/H circuit has one hold buffer, the hold buffer can drive all M ADC slices (e.g., FIG. 17A). If the T/H circuit has M number of hold buffers, several variations are available. In a first example, each hold buffer can drive a respective ADC slice. In a second example, each hold buffer can drive all M ADC slices. In a third example, each hold buffer can drive only a subset or fraction of M ADC slices. If the T/H circuit has N number of hold buffers, where N is less than M, several variations are also available. In a first example, each hold buffer can drive all M ADC slices. In one instance of the first example, a T/H circuit can have four sampling networks, and one hold buffer. The hold buffer can drive a total and all of 8 ADC slices. In a second example, each hold buffer can drive a subset or fraction of M ADC slices. In one instance of the second example, the T/H circuit can have four sampling networks, and four hold buffers (each hold buffer coupled to a corresponding sampling network). Each hold buffer can drive two ADC slices. The overall T/H circuit can drive a total of 8 ADC slices.

Method for Sampling with Calibration

FIG. 18 shows a flow diagram illustrating a method for sampling an input signal with calibration, according to some embodiments of the disclosure. In 1802, an input signal is buffered. In 1804, during a first phase, the buffered input signal is sampled onto a capacitor in a sampling network. In 1806, during a second phase, an additive dither signal is injected to the capacitor in the sampling network and outputting a held signal having an input signal sampled on the capacitor and the additive dither signal. In 1808, the held signal is buffered to generate a buffered signal for driving one or more analog-to-digital converters.

Balun and Matching Circuit

In the embodiments discussed above, the input to the sampling network has been depicted single-ended, that is, related to a signal that is delivered to the sampling network on a single line. However, in some embodiments, it may be desirable for the sampling network to receive a differential input and a differential output (e.g., the signal is delivered on two or more signal lines and output on two or more signal lines). The use of a differential input and output may allow for better common mode rejection, first order cancellation of even-order nonlinear terms, or smaller sample switch and transfer switch sizes.

In order to provide a differential input to the sampling network, a single-ended-to-differential conversion may be required. The following description relates to a wideband single-ended input capable of operating down to direct current (D.C.)—which may also be referred to as single-ended—a low input power, and a differential output while maintaining low noise and high linearity conditions. More specifically, the following embodiments may relate to a balun that is configured to receive a single-ended signal, and convert that signal to a differential signal at an output of the balun for input signals with a frequency at or above approximately lambda/2. As used herein, lambda may refer to the length of the balun as compared to the wavelength of the signal. For signals with an input frequency below lambda/2, the signal on the coupled path at the output of the balun may reduce in amplitude, and the net signal may become just the signal of the primary path. In other words, the signal may become single-ended, and the primary path signal may behave essentially as a single wire as the frequency of the signal approaches 0. Also, for example, if lambda/2 is centered at approximately 10 gigahertz (GHz), then the balun may be integrated on the same silicon as the sampling network, thus allowing the complete sampling system to be optimized for maximum performance.

In these embodiments, a differential sampling network may be modified such that it still maintains good common mode rejection, low even-ordered harmonics at low frequencies, and likewise equivalent sampling linearity when used in single-ended mode at low frequencies. Decreasing the full-scale input level may improve the second order terms by approximately 1 decibel (dB)/1 dB relative to signal level, and approximately 2 dB/1 dB for third-order terms. By decreasing the full-scale, desirable low-frequency second-order terms may be achieved. In this embodiment, for the sampling network may have increased independence from differential signals at low frequencies, and improved non-linearities in the single-ended mode.

Similarly, the track-and-hold circuit may have an amplifier after the sampling network, which may be generally similar to other amplifiers described herein such as amplifier 304 or some other amplifier discussed herein. Such an amplifier may take a discrete time-sampled voltage, increase the voltage level through amplification, and convert the voltage to a differential output that is to be digitized by the ADC. The amplifier may be chosen to not degrade the linearity of the signal over frequency, because it may be only operating on a held discrete-time voltage.

Generally, combining the characteristics of a balun with the characteristics of a modified differential sampling network and discrete-time amplifier may allow the system to be optimized and integrated into a single structure that may provide a single-ended input, a differential output, and wideband performance down to D.C. frequencies of the input signal. FIG. 19 shows an example signal flow diagram of a track and hold circuit with a balun, according to some embodiments of the disclosure. The track and hold circuit may include, for example, a balun 1905 that is coupled with a ground and a single-ended input (identified in FIG. 19 as Pin (dBm)). The track and hold circuit may further include a matching network 1910. The balun 1905 and the matching network 1910 will be described in greater detail below. The track and hold circuit may further include a buffer 1915, which may be similar to, for example, buffer 302 or some other buffer herein. The track and hold circuit may further include a sampling network 1920 which may be similar to, for example, switched-capacitor network 204, sampling network 802, or some other network discussed herein. The track and hold circuit may further include an amplifier 1925. In some embodiments, the amplifier 1925 may be a discrete-time amplifier, an amplifier such as amplifier 304, or some other amplifier.

FIG. 19 also depicts graphs 1930, 1935, and 1940 showing the relative transmission power of different lines over different frequencies. Specifically, graph 1930 depicts the relative power, in voltage-decibels (dBv), of the lines subsequent to the matching network 1910 that are marked as V₁ and V_(1N). Graph 1935 depicts the relative power, in dBv, of the lines subsequent to the sampling network 1920 that are marked as V_(1H) and V_(1HN). Graph 1940 depicts the relative power, in dBv, of the lines at the output of the track and hold circuit that are marked as V₀ and V_(0N). Generally, the x-axis of the graphs may depict increasing frequency as the graph progresses towards the right of the FIGURE, and by approximately equal to 0 at the far left of each of the graphs.

In FIG. 19, a single-ended input may be applied at the input of the circuit. The single-ended input is indicated by, for example, “Pin (dBm).” At low input signal frequencies (e.g., below lambda/2 as described above, and approaching D.C. frequencies), a signal may only be present at V₁ and V_(1H) as shown in, for example, graphs 1930 and 1935. The amplifier 1925 may increase the gain of the signal level, and convert the signal to differential at V_(1H) and V_(1HN) for digitization by an ADC at the output of the track and hold circuit.

As the input signal frequency starts to approach a fraction of lambda of the balun 1905, the signal at V₁ and V_(1H) begins to decrease and a signal approaching 180 degrees of V₁ begins to appear at V_(1N) and V_(1HN). In the mid-band frequencies, where the frequency may approach approximately lambda/2, V₁ and V_(1N) may be optimized for amplitude and phase balance throughout the system to maximize the sampling system performance. Additionally, as may be seen in graphs 1930 and 1935, the signal level at V₁, V_(1N), V_(1H), and V_(1HN) may be approximately half the level as the signal at P_(in) (which may be indicate by, for example, V₁ when the frequency approaches 0 in graph 1930). As such, the second and third order terms may be respectively 6 dB and 12 dB lower (as measured in relative dB with respect to graphs 1930, 1935, and 1940) in the mid-band frequency region or higher.

At higher input frequencies, e.g., significantly above lambda/2 (for example, at the far right of graphs 1930, 1935, and 1940), the outputs of the balun 1905 may begin to diverge and decrease (i.e., “roll-off”). Likewise, the signal outputs of the buffer 1915 and the sampling network 1920 may begin to decrease and the net signal at V₀ and V_(0N) may begin to decrease. By integrating the entire sampling system in the low-band, mid-band, and high-band, performance may be optimized for desired performance of the overall circuit.

To put it another way, the graphs 1930/1935/1940 may be seen to describe that from approximately DC to approximately 3 dB point, the sampling network 1920 may be sampling a single-ended signal. Therefore, the sampling network 1920 and the amplifier 1925 may be providing conversion from a single-ended signal to a differential signal. From the approximately −3 dB frequency point and beyond, the balun 1905 and matching network 1910 may provide the conversion between the single-ended signal to a differential signal, and then the sampling network 1920 may sample a differential signal. Once the balun 1905 and matching network 1910 convert the signal to a differential signal, the various benefits of differential signaling may be present and in addition the true/complement amplitudes may be reduced by approximately 6 dB.

FIG. 20 shows an example configuration of a balun and a related behavioral model, according to some embodiments of the disclosure. Generally, the balun theory of operation, for example of balun 1905, may be seen in the behavioral model 2001. The behavioral model 2001 may be described with respect to voltages V1 2005, V1 n 2010, and Vout 2015. FIG. 20 may further depict three graphs. Graph 2020 may show the output gain of the balun over increasing frequency for a given port. Graph 2025 may show output phase of the balun over increasing frequency for a given port.

As may be seen in FIG. 20, and particularly with respect to graphs 2020 and 2025, the behavioral model 2001 may show s-shaped parameters at the balun and amplifier output as a function of frequency.

At low frequency, an input signal is transferred directly to V1 2005, while V1N 2010 has little to no signal as shown in 2020. As the input signal frequency increases to the balun frequency of operation (e.g., lambda/2), v1N 2010 may increase and v1 2005 may decrease as shown in 2020. In addition, the phase of V1N 2010 may approach a 180 degree phase shift from V1 2005 as may be seen at 2025.

One may then consider a differential amplifier that is cascaded to the output of the balun. As the input frequency approaches lambda/2, the amplifier may provide differential gain. The output gain during the transition frequency may be from the balun operating as a power divider, and half the power may be seen at the termination resistors at nodes V1 2005 and V1N 2010.

In some embodiments, it may be desirable for the track and hold circuit to include a matching circuit that is to match an impedance of an input of the balun to an impedance of an element at the output of the balun. For example, a matching circuit such as matching circuit 1910 may match an impedance of the balun 1905 to an impedance of the buffer 1915. FIG. 21 shows an example configuration of a balun with a matching circuit, according to some embodiments of the disclosure.

Specifically, element (a) shows an example topology of the matching circuit 2101. Element (b) shows an example circuit diagram of a balun with a matching circuit at 2102. Specifically, element (b) may show a balun 2102 (which may be similar to, for example, balun 1905) with matching circuits 2107 and 2108 coupled to the outputs of the balun 2102. The matching circuits 2107 and 2108 may be similar to, for example, matching circuit 2101.

The matching circuit 2101 may include an inductor 2104, a resistor R1 at 2103, a resistor R2 at 2105, and a capacitor at 2106. It will be understood that this topology is one example topology of the matching circuit, and other embodiments may have more or fewer elements, elements in a different configuration, or additional or alternative active or passive elements.

Generally, the resistor R1 at 2103 may have a resistance value that is based on a desired low-frequency impedance match, and may typically have a value between approximately 40 ohms and approximately 60 ohms. In some embodiments, the value of the resistor R1 at 2103 may be approximately 50 ohms. The parallel combination of R1 at 2103 and R2 at 2105 may be chosen to be between approximately 20 ohms and 30 ohms and, in some embodiments, may be approximately 25 ohms. The capacitance value of the capacitor at 2106 may be chosen based on the transition frequency of the matching circuit 2101, and particularly may be chosen to set the transition frequency of the matching circuit 2101 to be commensurate with the transition frequency lambda/2 of the balun. In some embodiments, the capacitor 2106 may have a capacitance value between approximately 1 picofarad (pF) and approximately 5 pF. The inductor 2104 may extend the analog input bandwidth of the matching circuit 2101, and may be chosen to resonate out parasitic capacitance in the ADC front-end. Generally, the value of various elements herein such as R1 at 2103, R2 at 2105, capacitor 2106, etc. may be chosen such that the resistance/capacitance (RC) pole and zero are proportional to the electrical length of the balun. As frequency increases from DC, and the balun begins to transition from a single-ended output to outputting a differential signal, the RC-tuning impedance may transition proportionally. The values of the various resistors or capacitors may be selected to keep the gain or phase of the balun relatively flat.

Generally, embodiments herein may have a variety of characteristics. For example, the user interface may be a single-ended input (e.g. Pin) of FIG. 19. Additionally, the input-signal power-level requirements may be compatible with a low-power, high-linearity front-end-signal-conditioning front end. The output signal level may be compatible with high-performance ADC designs as described herein.

The sampling network (e.g., sampling network 1920) may have single-ended operation down to an input-signal frequency of 0, if needed. However, not all balun topologies may provide this feature, so it may be desirable to include a balun that operates as a single-ended output at the input-signal frequency of 0. In the frequency region under (12*10⁸/lambda), the sampling network may be optimized for the desired single-ended performance. In the frequency region of approximately (12*10⁸/lambda) where the balun and the sampling network transition from single-ended to differential operation, the characteristics of the balun 1905 and the sampling network 1920 may be optimized as a single unit. For example, the balun 1905 and sampling network 1920 may be optimized to gain response flatness over frequency, and minimizing even-ordered harmonic terms due to amplitude and phase mismatch.

In the frequency region of approximately (6*10⁸/lambda), the balun 1905 and the sampling network 1920 may operate as a differential system. The even and odd order non-linear terms may be improved by reduced swing due to differential operation, improved differential amplitude matching, and improved differential phase matching.

Track and Hold Circuit with Balun

FIG. 22 shows an alternative example configuration of a track and hold circuit with a balun, according to some embodiments of the disclosure. Generally, the circuit may include a balun 2205, a buffer 2210, an amplifier 2220, a sampling network 2215, and a chopping circuit 2225. It will be understood that although the sampling network 2215 and the chopping circuit 2225 may include three separate pathways, in some embodiments they may include more or fewer pathways as described above with respect to other embodiments.

The balun 2205 may be similar to, for example, balun 1905. In some embodiments, the balun 2205 may further be seen to include a matching network such as matching network 1910 or 2101. As noted above, the balun 2205 may be desired to convert a single-ended input (e.g., Vin) to a differential output (e.g., Vin_diff). However, in some embodiments, the balun 2205 may be insufficient on its own to achieve the desired high performance over a wide bandwidth. For example, as described above with respect to FIG. 19 and, more particularly, graphs 1930/1935/1940, the response of the balun may shift from being single-ended at low input frequency ranges (e.g., frequency ranges up to approximately 2 GHz) to a differential output at higher input frequencies in the range of approximately 10 GHz. This shift may present a challenge to a following sampling network, as the sampling network may need to be capable of handling fully single-ended inputs at frequencies up to approximately 2 GHz and differential inputs at higher frequencies without degrading the performance below target specifications and without requiring long reconvergence of background calibrations. However, other elements of the track and hold circuit may, when combined with the balun 2205, allow for the target specifications to be met.

For example, the buffer 2210 may be similar to, for example, buffer 202 or some other buffer as described herein. Specifically, the buffer 2210 may be a small-input/full-scale buffer. Such a buffer may improve second-order and third-order distortion in the continuous-time domain (which may also follow frequency of an input signal). For example, by reducing the input full-scale by between approximately 9 and approximately 12 dB, the second order harmonic distortion may improve by between approximately 9 and approximately 12 dB, and the third order harmonic distortion may improve by between approximately 18 and approximately 24 dB. In some embodiments, this reduction in amplitude may degrade the signal-to-noise ration (SNR) of the circuit by between approximately 9 and approximately 12 dB. However, the subsequent discrete-time amplification limits the total SNR degradation to between approximately 4.5 and approximately 6 dB. This total SNR degradation may, in some embodiments, be compensated for by increasing the sampling capacitance by 3×-4× (e.g. from approximately 200 femtofarads (fF) to between approximately 600 and approximately 800 fF).

The amplifier 2220 may, for example, be similar to amplifier 304 or amplifier 1925 as discussed above. Specifically, the amplifier 2220 may be an open-loop or a closed-loop amplifier. In some embodiments, open-loop implementations may have desirable characteristics such as faster or lower-power operation. As noted, the amplifier 2220 may be a discrete-time amplifier, and its non-linearity may be calibrated using dither injected by the sampling network 2215 or the chopping circuit 2225. This dither-based calibration may be input-frequency independent. In some embodiments, the amplifier 2220 may be in the form of an open-loop differential pair, with or without cascoding followed by an optional push-pull source follower.

The sampling network 2215 may be similar to, for example, sampling network 1920, sampling networks 802/804, or some other sampling network as described herein. Generally, the sampling network 2215 may be optimized for both single-ended and differential operation, and may include dither injection. The dither injection may be desirable to calibrate the non-linearity of the amplifier 2220 or other non-idealities in the following cores. In some embodiments, the injected dither may be single-bit or multi-bit as described above. In some embodiments, it may be injected on the same sample capacitance or on a separate dither capacitance. It may also be used to calibrate the memory errors on the amplifier input, and the kick-back errors on the input driver.

The chopping circuit 2225 may be similar to, and share one or more characteristics with, a chopping circuit such as chopper 1402 or some other chopper herein. The chopping circuit 2325 may be desirable because the response of the balun 2205 may be frequency-dependent as described above (e.g., whether it's a single-ended output or a differential output). The buffer 2210 and the sampling network 2215 may be configured to respond to the frequency-dependent output changes. However, the amplifier 2220 may have undesirable even-order distortion performance at low input frequencies. Chopping may desensitize the response against even-order distortion by randomizing the even-order distortion and spreading it in the noise floor.

FIG. 23 shows an alternative example configuration of a track and hold circuit with a balun, according to some embodiments of the disclosure. Specifically, the track and hold circuit may include a balun 2305 which may be similar to, for example, balun 2205 of FIG. 22. As noted, the balun in various embodiments may include a differential output. FIG. 23 depicts an example of the configuration of such a differential output, and how a circuit may be designed to accommodate for the same.

Specifically, the balun 2305 may have a first output path as indicated by the output V_(inp) in FIG. 23. Such an output path may include a buffer 2310 a, a sampling network 2315 a, a chopping circuit 2325 a, and an amplifier 2320 a which may be respectively similar to, and share one or more characteristics with, buffer 2210, sampling network 2215, chopping circuit 2225, and amplifier 2220. It will be noted, however, that the sampling network 2315 a and the chopping circuit 2325 a may only include a single pathway rather than the 3 pathways depicted in, for example, sampling network 2215 and chopping circuit 2225.

The balun 2305 may have a second output path as indicated by the output signal V_(inn). Similarly to the first output path, the second output path may include a buffer 2310 b, a sampling network 2315 b, a chopping circuit 2325 b, and an amplifier 2320 b, which may be respectively similar to, and share one or more characteristics with, buffer 2210, sampling network 2215, chopping circuit 2225, and amplifier 2220. Similarly to sampling network 2315 a and chopping circuit 2325 a, it will be noted that sampling network 2315 b and chopping circuit 2325 b may only include a single pathway rather than the 3 pathways depicted in, for example, sampling network 2215 and chopping circuit 2225.

It will be understood that in some embodiments certain elements (e.g., buffers 2310 a and 2310 b, sampling network 2315 a and 2315 b, chopping circuit 2325 a and 2325 b, and amplifiers 2320 a and 2320 b) may be identical to one another, while in other embodiments an element of one signal pathway may be different than an element of another signal pathway. Additionally, it will be understood that the circuits depicted herein are intended as example embodiments and other embodiments may have more or fewer elements, different elements, elements that are communicatively coupled differently, etc.

EXAMPLES

Example 1001 is track and hold circuit comprising a sampling buffer, a sampling network receiving a buffered input from the sampling buffer, and a hold buffer receiving a held signal from the sampling network.

In Example 1002, the track and hold circuit of Example 1001 can further the sampling network comprising a node for receiving an additive dither.

In Example 1003, the track and hold circuit of Example 1001 or 1002 can further include a chopper integrated with the sampling network.

In Example 1004, the track and hold circuit of any one of Examples 1001-1003 can further include one or more further sampling networks in parallel.

In Example 1005, the track and hold circuit of Example 1004 can further include the sampling networks sampling the buffered input from the sampling buffer in a time-interleaved manner.

In Example 1006, the track and hold circuit of Example 1004 or 1005 can further include the sampling networks sampling the buffered input from the sampling buffer in a randomized time-interleaved manner.

In Example 1007, the track and hold circuit of any one of Examples 1004-1006 can further include the sampling networks being configurable to sample the buffered input in different modes.

In Example 1008, the track and hold circuit of any one of Examples 1001-1007 can further include one or more further hold buffers.

In Example 1009, the track and hold circuit of any one of Examples 1004-1007 can further include one or more further hold buffers each dedicated to each sampling network.

Example 101 is a method comprising: buffering an input signal; during a sampling phase, sampling the buffered input signal onto a capacitor; and during a hold phase, connecting a node having a dither signal to the capacitor to output a held signal having the dither signal; buffering the held signal.

In Example 102, the method of Example 101 can further include randomly chopping the held signal prior to buffering the held signal.

In Example 103, the method of Example 101 or 102 can further include driving a plurality of ADCs which are operating in a time-interleaved manner.

In Example 104, the method of any one of Examples 101-103 can further include calibrating, based on the additive dither, one or more of the following non-idealities: non-linearity of the hold phase of the track and hold circuit, non-linearity of one or more analog-to-digital converters being driven by the track and hold circuit, gain mismatch between a plurality of time-interleaved analog-to-digital converters being driven by the track and hold circuit, offset mismatch between the plurality of time-interleaved analog-to-digital converters.

In Example 105, the method of any one of Examples 101-104 can further include calibrating, based on the multiplicative dither, offset mismatch between a plurality of time-interleaved analog-to-digital converters being driven by the track and hold circuit.

Example A is an apparatus comprising means for implementing/carrying out any one of the methods described herein.

Example 1 is a low-power track and hold circuit, the track and hold circuit comprising: a sampling buffer; a sampling network, with dither injection, to receive a buffered input from the sampling buffer; and a hold buffer to receive a held signal from the sampling network. The sampling buffer and/or the hold buffer can be omitted in some cases.

In Example 2, Example 1 can optionally include the sampling network comprising a node to receive an additive dither.

In Example 3, Example 1 or 2 can optionally include a chopper integrated with the sampling network to inject a multiplicative dither.

In Example 4, any one of Examples 1-3 can optionally include the sampling network comprising a switched-capacitor network to sample the buffered input from the sampling buffer onto one or more capacitors.

In Example 5, any one of Examples 1-4 can optionally include the hold buffer (and/or the sampling buffer) comprising a variable gain amplifier. In some cases, a variable gain amplifier is added in front of the track and hold circuit.

In Example 6, Examples 5 can optionally include a signal level detector to detect an overload condition and generate a gain control signal of the variable gain amplifier.

In Example 7, any one of Examples 2-6 can optionally include the sampling network comprising: an input switch to receive the buffered input from the sampling buffer; a sampling switch to sample the buffered input onto a capacitor during a sampling phase; and a dither injection switch to connect the capacitor to a node having the additive dither.

In Example 8, any one of Examples 1-7 can optionally include the sampling network further comprising an output switch to connect a capacitor in the sampling network to the hold buffer during a hold phase.

In Example 9, any one of Examples 1-8 can optionally include one or more further hold buffers in parallel with the hold buffer to receive the held signal from the sampling network, wherein the hold buffer and the one or more further hold buffers drive respective analog-to-digital converters.

In Example 10, any one of Examples 1-9 can optionally include one or more further sampling networks in parallel with the sampling network, wherein the sampling network and the one or more further sampling networks sample the buffered input from the sampling buffer in a time-interleaved manner.

In Example 11, any one of Examples 1-10 can optionally include one or more further sampling networks in parallel with the sampling network, wherein the sampling network and the one or more further sampling networks sample the buffered input from the sampling buffer in a randomized time-interleaved manner.

In Example 12, any one of Examples 1-11 can optionally include the sampling network and the one or more further sampling networks being configurable to sample the buffered input in different modes.

In Example 13, any one of Examples 10-12 can optionally include one or more further hold buffers in parallel with the hold buffer, wherein the one or more further hold buffers receive one or more respective held signals from the one or more further sampling networks.

In Example 14, any one of Examples 1-13 can optionally include two serial switches including a first switch in series with a second switch, wherein the first switch couples an output of the hold buffer to the second switch, the second switch couples the first switch to an input of a first one of a plurality of analog-to-digital converters, and the second switch operates at a slower speed than the first switch.

Example 15 is a method for sampling an input signal with calibration, the method comprising: buffering an input signal; during a first phase, sampling the buffered input signal onto a capacitor in a sampling network; during a second phase, injecting an additive dither signal to the capacitor in the sampling network and outputting a held signal having an input signal sampled on the capacitor and the additive dither signal; and buffering the held signal to generate a buffered signal for driving one or more analog-to-digital converters.

In Example 16, Example 15 can optionally include randomly chopping a signal in the sampling network based on a multiplicative dither.

In Example 17, Example 15 or 16 can optionally include the one or more analog-to-digital converters comprising time-interleaved analog-to-digital converters.

In Example 18, any one of Examples 15-17 can optionally include interleaving a further sampling network to sample the buffered input signal during the second phase.

In Example 19, Example 18 can optionally include the further sampling network being selected at random from a plurality of available sampling networks.

Example 20 is a time-interleaved analog-to-digital converter with calibration, the time-interleaved analog-to-digital converter comprising: a plurality of analog-to-digital converters operating in a time-interleaved fashion; and an open loop track and hold circuit operating at a full-speed of the time-interleaved analog-to-digital converter and driving the plurality of analog-to-digital converters, wherein the open loop track and hold circuit comprises at least one buffer and a sampling network with dither injection.

Example 21 includes a track and hold circuit comprising: a plurality of analog-to-digital converter (ADC) slices; a first signal pathway that includes a first sampling network, wherein the first signal pathway is selectively couplable to the plurality of ADC slices by a first switch; and a second signal pathway that includes a second sampling network, wherein the second signal pathway is selectively couplable to a portion of the plurality of ADC slices, wherein the portion is a number of ADC slices that is less than a number of the plurality of ADC slices.

Example 22 includes the track and hold circuit of example 21, further comprising a third signal pathway that includes a third sampling network, wherein the third signal pathway is selectively couplable to a second portion of the plurality of ADC slices, wherein the second portion is different than the first portion.

Example 23 includes the track and hold circuit of example 21, wherein the first signal pathway includes a first buffer that is between the first sampling network and an input to the track and hold circuit

Example 24 includes the track and hold circuit of example 23, wherein the second signal pathway includes a second buffer that is between the second sampling network and the input to the track and hold circuit.

Example 25 includes the track and hold circuit of any of examples 21-24, further comprising a second switch that is to selectively couple the second sampling network to the portion of the plurality of ADC slices.

Example 26 includes the track and hold circuit of any of examples 21-24, wherein the switch is between the first sampling network and an input to the track and hold circuit.

Example 27 includes the track and hold circuit of any of examples 21-24, further comprising a buffer between the first signal pathway and the plurality of ADC slices.

Example 28 includes the track and hold circuit of example 27, wherein the switch is between the first sampling network and the buffer.

Example 29 includes the track and hold circuit of example 27, wherein the switch is between the buffer and the plurality of ADC slices.

Example 30 includes a method of forming a track and hold circuit, wherein the method comprises: coupling a first input buffer to an input of the track and hold circuit; coupling, by a first switch, a first signal pathway to a plurality of analog-to-digital converter (ADC) slices, wherein the first signal pathway includes a first sampling network communicatively between the first input buffer and the plurality of ADC slices; and coupling, by a second switch, a second signal pathway to a first subset of the plurality of ADC slices, wherein the second signal pathway includes a second sampling network.

Example 31 includes the method of example 30, further comprising coupling a second input buffer communicatively between the input of the track and hold circuit and an input of the second signal pathway.

Example 32 includes the method of example 30, further comprising coupling, by a third switch, a third signal pathway to a second subset of the plurality of ADC slices, wherein the third signal pathway includes a third sampling network.

Example 33 includes the method of example 32, wherein the second subset of the plurality of ADC slices is less than the plurality of ADC slices, and is different than the first subset of the plurality of ADC slices.

Example 34 includes the method of any of examples 30-33, further comprising coupling a second input buffer between the input of the track and hold circuit and the second signal pathway.

Example 35 includes an electronic device comprising: a signal input; a plurality of analog-to-digital converter (ADC) slices; a first signal pathway communicatively positioned between the signal input and the plurality of ADC slices, wherein the first signal pathway includes a first sampling network and a first input buffer; and a second signal pathway communicatively positioned between the signal input and a subset of the plurality of ADC slices, wherein the second signal pathway includes a second sampling network and a second input buffer; wherein the subset of the plurality of ADC slices includes a number of ADC slices that is less than a number of the plurality of ADC slices.

Example 36 includes the electronic device of example 35, further comprising a third signal pathway communicatively positioned between the signal input and a second subset of the plurality of ADC slices, wherein the third signal pathway includes a third sampling network and a third input buffer.

Example 37 includes the electronic device of examples 35 or 36, further comprising: a first switch to communicatively couple the first sampling network to the plurality of ADC slices; and a second switch to communicatively coupled the second sampling network to the subset of the plurality of ADC slices.

Example 38 includes the electronic device of example 37, wherein the first switch is between the first sampling network and the signal input.

Example 39 includes the electronic device of example 37, wherein the first switch is between the first sampling network and the first input buffer.

Example 40 includes the electronic device of example 37, wherein the first switch is between the first sampling network and the plurality of ADC slices.

Example 41 includes a track-and-hold circuit comprising: a balun to convert a single-ended signal to a differential signal; a buffer coupled with the output of the balun; a sampling network coupled with the output of the buffer, wherein the sampling network includes dither injection; and a discrete-time amplifier coupled with an output of the sampling network.

Example 42 includes the track-and-hold circuit of example 41, wherein the balun is to convert the single-ended signal to the differential signal if the single-ended signal has a frequency above a threshold.

Example 43 includes the track-and-hold circuit of example 41, wherein the balun is to output the differential signal on a first signal path and a second signal path, and wherein the buffer is a first buffer in the first signal path, and wherein the track-and-hold circuit further comprises a second buffer in the second signal path.

Example 44 includes the track-and-hold circuit of example 41, wherein the sampling network is operable to sample a single-ended signal and a differential signal.

Example 45 includes the track-and-hold circuit of example 41, wherein the discrete-time amplifier is an open-loop or a closed-loop amplifier.

Example 46 includes the track-and-hold circuit of any of examples 41-45, further comprising a matching network that is to match an impedance of the balun to an impedance of the buffer.

Example 47 includes the track-and-hold circuit of any of examples 41-45, further comprising a chopper integrated with the sampling network, wherein the chopper is to inject the dither.

Example 48 includes a track-and-hold circuit comprising: a balun that is to receive a single-ended input signal and output one of a single-ended output signal based on the single-ended input signal and a differential output signal based on the single-ended input signal; a sampling network with dither injection coupled with an output of the balun; and a matching circuit that is to match an impedance of the balun with an impedance of the sampling network.

Example 49 includes the track-and-hold circuit of example 48, wherein the balun is to output the single-ended output signal if a frequency of the single-ended input signal is below a threshold frequency.

Example 50 includes the track-and-hold circuit of example 49, wherein the threshold frequency is below 2 gigahertz (GHz).

Example 51 includes the track-and-hold circuit of example 48, wherein the balun is to output the differential output signal if a frequency of the single-ended input signal is above a threshold frequency.

Example 52 includes the track-and-hold circuit of example 51, wherein the threshold frequency is 8 gigahertz (GHz).

Example 53 includes the track-and-hold circuit of any of examples 48-52, wherein the matching circuit is a first matching circuit that is coupled with a first output of the balun, and further comprising a second matching circuit that is coupled with a second output of the balun.

Example 54 includes the track-and-hold circuit of any of examples 48-52, wherein the matching circuit includes a resistor with a value that is based on a low-frequency impedance match of the circuit.

Example 55 includes the track-and-hold circuit of any of examples 48-52, wherein the matching circuit includes a capacitor with a value that is based on a transition frequency of the balun.

Example 56 includes a method of forming a track-and-hold circuit, wherein the method comprises: coupling a buffer with an output of a balun, wherein the balun is to convert a single-ended signal to a differential signal; coupling a sampling network with an output of the buffer, wherein the sampling network includes dither injection; and coupling a discrete-time amplifier with an output of the sampling network.

Example 57 includes the method of example 56, wherein the balun includes a matching network that is to match an impedance of the balun to an impedance of the buffer.

Example 58 includes the method of example 56, further comprising a chopper integrated with the sampling network, wherein the chopper is to inject the dither.

Example 59 includes the method of any of examples 56-58, wherein the balun is to convert the single-ended signal to the differential signal if the single-ended signal has a frequency above a threshold.

Example 60 includes the method of any of examples 56-58, wherein the discrete-time amplifier is an open-loop or a closed-loop amplifier.

VARIATIONS AND IMPLEMENTATIONS

Herein, switches represent electronic circuitry which can be controlled to conduct a signal (e.g., current) or not conduct the signal (e.g., current). In practice, switches can be implemented using transistors. By biasing the transistors appropriately, the transistor can conduct current or not conduct current (be “on” or “off” respectively). When the switch is closed or “on”, current conducts to complete the circuit path. When a switch is opened or “off”, current does not conduct and the circuit path is open. Switches can effectively connect/couple one part of a circuit to another part of a circuit, or disconnect/decouple one part of a circuit to another part of a circuit.

Note that the activities discussed above with reference to the FIGURES are applicable to any integrated circuits that involve processing analog signals and converting the analog signals into digital data using one or more ADCs. In certain contexts, the features discussed herein related to ADCs in general, including, e.g., ADCs of various flavors including pipeline ADCs, delta sigma ADCs, successive approximation register ADCs, multi-stage ADCs, time-interleaved ADCs, randomized time-interleaved ADCs, etc. The features can be particularly beneficial to high speed ADCs, where input frequencies are relatively high in the giga-hertz range. The ADC can be applicable to medical systems, scientific instrumentation, wireless and wired communications systems (especially systems requiring a high sampling rate), radar, industrial process control, audio and video equipment, instrumentation, and other systems which uses ADCs. The level of performance offered by high speed ADCs can be particularly beneficial to products and systems in demanding markets such as high-speed communications, medical imaging, synthetic aperture radar, digital beam-forming communication systems, broadband communication systems, high performance imaging, and advanced test/measurement systems (oscilloscopes).

The present disclosure encompasses apparatuses which can perform extraction and calibration of non-idealities described herein. Parts of various apparatuses can include electronic circuitry to perform the functions described herein. The circuitry can operate in analog domain, digital domain, or in a mixed-signal domain. In some cases, one or more parts of the apparatus can be provided by a processor specially configured for carrying out the functions described herein (e.g., control-related functions, timing-related functions). In some cases that processor can be an on-chip processor with the ADC. The processor may include one or more application specific components, or may include programmable logic gates which are configured to carry out the functions describe herein. In some instances, the processor may be configured to carrying out the functions described herein by executing one or more instructions stored on a non-transitory computer medium.

Note that with the numerous examples provided herein, interaction may be described in terms of two, three, four, or more electrical components or parts. However, this has been done for purposes of clarity and example only. It should be appreciated that the system can be consolidated in any suitable manner. Along similar design alternatives, any of the illustrated components, modules, blocks, and elements of the FIGURES may be combined in various possible configurations, all of which are clearly within the broad scope of this Specification. In certain cases, it may be easier to describe one or more of the functionalities of a given set of flows by only referencing a limited number of electrical elements. It should be appreciated that the electrical circuits of the FIGURES and its teachings are readily scalable and can accommodate a large number of components, as well as more complicated/sophisticated arrangements and configurations. Accordingly, the examples provided should not limit the scope or inhibit the broad teachings of the electrical circuits as potentially applied to a myriad of other architectures.

Note that in this Specification, references to various features (e.g., elements, structures, modules, components, steps, operations, characteristics, etc.) included in “one embodiment”, “example embodiment”, “an embodiment”, “another embodiment”, “some embodiments”, “various embodiments”, “other embodiments”, “alternative embodiment”, and the like are intended to mean that any such features are included in one or more embodiments of the present disclosure, but may or may not necessarily be combined in the same embodiments. It is also important to note that the functions described herein illustrate only some of the possible functions that may be executed by, or within, systems/circuits illustrated in the FIGURES. Some of these operations may be deleted or removed where appropriate, or these operations may be modified or changed considerably without departing from the scope of the present disclosure. In addition, the timing of these operations may be altered considerably. The preceding operational flows have been offered for purposes of example and discussion. Substantial flexibility is provided by embodiments described herein in that any suitable arrangements, chronologies, configurations, and timing mechanisms may be provided without departing from the teachings of the present disclosure. Numerous other changes, substitutions, variations, alterations, and modifications may be ascertained to one skilled in the art and it is intended that the present disclosure encompass all such changes, substitutions, variations, alterations, and modifications as falling within the scope of the appended claims or examples described herein. Note that all optional features of the apparatus described above may also be implemented with respect to the method or process described herein and specifics in the examples may be used anywhere in one or more embodiments. 

What is claimed is:
 1. A track-and-hold circuit comprising: a balun to convert a single-ended signal to a differential signal; a buffer coupled with the output of the balun; a sampling network coupled with the output of the buffer, wherein the sampling network includes dither injection; and a discrete-time amplifier coupled with an output of the sampling network.
 2. The track-and-hold circuit of claim 1, wherein the balun is to convert the single-ended signal to the differential signal if the single-ended signal has a frequency above a threshold.
 3. The track-and-hold circuit of claim 1, wherein the balun is to output the differential signal on a first signal path and a second signal path, and wherein the buffer is a first buffer in the first signal path, and wherein the track-and-hold circuit further comprises a second buffer in the second signal path.
 4. The track-and-hold circuit of claim 1, wherein the sampling network is operable to sample a single-ended signal and a differential signal.
 5. The track-and-hold circuit of claim 1, wherein the discrete-time amplifier is an open-loop or a closed-loop amplifier.
 6. The track-and-hold circuit of claim 1, further comprising a matching network that is to match an impedance of the balun to an impedance of the buffer.
 7. The track-and-hold circuit of claim 1, further comprising a chopper integrated with the sampling network, wherein the chopper is to inject the dither.
 8. A track-and-hold circuit comprising: a balun that is to receive a single-ended input signal and output one of a single-ended output signal based on the single-ended input signal and a differential output signal based on the single-ended input signal; a sampling network with dither injection coupled with an output of the balun; and a matching circuit that is to match an impedance of the balun with an impedance of the sampling network.
 9. The track-and-hold circuit of claim 8, wherein the balun is to output the single-ended output signal if a frequency of the single-ended input signal is below a threshold frequency.
 10. The track-and-hold circuit of claim 9, wherein the threshold frequency is below 2 gigahertz (GHz).
 11. The track-and-hold circuit of claim 8, wherein the balun is to output the differential output signal if a frequency of the single-ended input signal is above a threshold frequency.
 12. The track-and-hold circuit of claim 11, wherein the threshold frequency is 8 gigahertz (GHz).
 13. The track-and-hold circuit of claim 8, wherein the matching circuit is a first matching circuit that is coupled with a first output of the balun, and further comprising a second matching circuit that is coupled with a second output of the balun.
 14. The track-and-hold circuit of claim 8, wherein the matching circuit includes a resistor with a value that is based on a low-frequency impedance match of the circuit.
 15. The track-and-hold circuit of claim 8, wherein the matching circuit includes a capacitor with a value that is based on a transition frequency of the balun.
 16. A method of forming a track-and-hold circuit, wherein the method comprises: coupling a buffer with an output of a balun, wherein the balun is to convert a single-ended signal to a differential signal; coupling a sampling network with an output of the buffer, wherein the sampling network includes dither injection; and coupling a discrete-time amplifier with an output of the sampling network.
 17. The method of claim 16, wherein the balun includes a matching network that is to match an impedance of the balun to an impedance of the buffer.
 18. The method of claim 16, further comprising a chopper integrated with the sampling network, wherein the chopper is to inject the dither.
 19. The method of claim 16, wherein the balun is to convert the single-ended signal to the differential signal if the single-ended signal has a frequency above a threshold.
 20. The method of claim 16, wherein the discrete-time amplifier is an open-loop or a closed-loop amplifier. 